A buoyant clamp assembly and method for clamping an elongate member to a support member. The buoyant clamp assembly includes a flexible strap having first and second ends. Affixed to the exterior of the flexible strap are wear blocks. A highly frictional layer is attached to the interior of the flexible strap to increase friction between the clamping assembly and the elongate or support member. The flexible strap extends substantially around the elongate and support members. The first and second ends are adapted to be coupled to each other via a loop member. The clamp assembly also includes a tensioner assembly having first and second tensioner bars spaced parallel to one another. Capture bolts affixed to the tensioner assembly prevent the first and second tensioner bars from separating. Each of the first and second tensioner bars includes a bullnose face and the bullnose faces are in opposing relationship to one another. The tensioner assembly also includes adjusting members for adjusting the spacing between the first and second tensioner bars. The first end of the flexible strap extends around the support member, through the gap between the tensioner bars, through the loop member and doubles back on itself through the gap between the tensioner bars. The doubled-back portion of the flexible strap is positioned between the first portion of the flexible strap passing through the gap and the first tensioner bar. A highly frictional layer is attached to the flexible strap in the area where the flexible strap doubles back on itself so that the highly frictional layer is between the flexible strap layers. The holding ability of the clamp assembly is attributable to the tensioner assembly, the doubling back of the flexible strap and the friction multiplier.
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1. A method of securing an elongate member to a support member comprising the steps of:
positioning a flexible strap having first and second ends substantially around adjacent elongate and support members; inserting the first end of the flexible strap through a gap between a pair of tensioner bars; looping the first end of the flexible strap tbrough a loop member attached to the second end of the flexible strap; passing the first end of the flexible strap back through the gap between the pair of tensioner bars, the first end of the flexible strap doubling back in frictional contact with itself as it extends through the gap; and tensioning the flexible strap to secure the elongate and support members.
10. A method of securing two or more elongate members to a support member comprising the steps of:
receiving elongate members into a receiving block having a receptacle for each elongate member; positioning a flexible strap having first and second ends substantially around the elongate members and adjacent support member; inserting the first end of the flexible strap through a gap between a pair of tensioner bars; looping the first end of the flexible strap through a loop member attached to the second end of the flexible strap; passing the first end of the flexible strap back through the gap between the pair of tensioner bars, the first end of the flexible strap doubling back in frictional contact with itself as it extends through the gap; and tensioning the flexible strap to secure the elongate and support members.
18. A method of securing a first cylindrical member to a second cylindrical member using a clamp assembly having a flexible strap and a tensioner assembly, the tensioner assembly having first and second bars with an adjustable gap therebetween, the method comprising the steps of:
extending the flexible strap through the adjustable gap; substantially encompassing the combination of the first and second cylindrical members with the flexible strap; extending a first end of the flexible strap through the adjustable gap; looping the flexible strap first end through a loop member attached to a second end of the flexible strap; passing the first end of the flexible strap back through the adjustable gap, the first end of the flexible strap doubling back in frictional contact with itself as it extends through the gap; pulling the first end of the flexible strap to snug the flexible strap around the combination of the first and second cylindrical members; and tensioning the flexible strap to secure the first and second cylindrical members.
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This application is a divisional of U.S. application Ser. No. 09/766,947, filed Jan. 22, 2001 now U.S. Pat. No. 6,612,520, which is incorporated herein in its entirety by reference.
Not applicable.
Not applicable.
1. Field of the Invention
The present invention relates generally to clamp assemblies for connecting one member to a support member, and more particularly to a high strength buoyant clamp assembly to attach a pipe or line, such as an umbilical line, to another pipe, and shields the pipe and line from contact with each other and surrounding media. The present invention is particularly adapted for use as a subsea clamp assembly to attach an umbilical line to any type of subsea riser pipe or wireline.
2. Description of the Related Art
The need often arises for a clamp assembly to attach a cable, hose, or pipe to a support member or pipe. Typically, the cable, hose, or pipe is run along the length of the support member or pipe. Many types of clamp assemblies have been used to secure the members to one another. The members may be horizontally positioned or vertically positioned. It is generally desirable that the clamp assembly be capable of quick installation while securely attaching the clamped members to one another. Additionally, it is desirable that the clamp assembly be lightweight and relatively inexpensive.
In the offshore drilling and production industry, it is frequently necessary to run umbilical lines hundreds and even thousands of feet below the support vessel or drilling or production platform down to the sea floor and possibly beyond. Typically, the umbilical lines, which may include electric, MUX (fiber optics), and hydraulics, are required to be attached to a support member, such as a choke or kill line for workover/completion risers, or mud line on a subsea riser system. Due to the high cost of working in such environments, it is critical that the clamp assembly be easy to install, quickly installed, reliable, durable, and dependable to firmly secure the clamped members. Failure of a clamp during drilling can cause unnecessary expense as broken pieces of the clamp assembly may descend into the well, thereby clogging or jamming the lines and other essential equipment during the drilling process. Fishing for broken clamp assembly pieces in a well can be time consuming and result in increased drilling and production delays. Thus, a buoyant clamp assembly would eliminate the likelihood of clamp failure interfering with the drilling process. During the drilling process, the clamp assembly is subjected to significant jarring and contact with the inside of the well casing. Thus, the clamp must be strong enough to withstand constant striking and jolting against the inner casing. In the offshore industry, limited platform space is available for the workman to install the clamp assemblies and sometimes the workman is limited to accessing the riser from a single side. Thus, it is vitally important that the clamp assembly be easy to install from a location on both sides or sometimes one side of the riser.
In the past, riser clamps comprised of two half sections joined about the riser have been used. Typically, these riser clamps were fabricated completely from steel or stainless steel. Such clamps were subject to rust and corrosion and added unwanted weight to the entire clamped assembly causing an increased risk of assembly parts interfering with the drilling process in the event of a failure. Additionally, such clamps tended to be time consuming to install. Another type of riser clamp that has been used is similar to a large hose clamp which screws tight and directly clamps the clamped members to the support member. This type of clamp is subject to damaging the clamped members and is time consuming to install, and does not accommodate size variances of the umbilical(s). Not being able to accommodate size variances can have disastrous consequences if the umbilical hose slips downward and loops inside the marine drill riser or in open water. A MUX line loses its signal transmission if a loop results because of poor clamping. Still other types of prior art clamps have bodies molded of urethane. Typically, a mold relief substance penetrates the skin of the urethane-molded bodies during the molding process and results in the body surface having very low frictional capabilities. It is not desirable to have low frictional capabilities between the clamp body and the riser and/or umbilical members.
Applicant's U.S. Pat. No. 5,598,995 to Meuth discloses a clamp assembly having a receptacle adapted to at least partially receive an elongate member, a pair of flexible support straps connected to the receptacle, and a pair of flexible clamping straps. The pair of flexible support straps are capable of matingly engaging one another around a support member and the pair of flexible clamping straps are capable of matingly engaging one another around one or more elongate members and the support member. The receptacle includes a receptacle body made of high density polyurethane foam having a recess therein adapted to at least partially receive the elongate member. A pivotable buckle is attached to one of the flexible clamping straps for securely tensioning the pair of clamping straps around the elongate member or members and the support member. An adjustment assembly is attached to one of the flexible clamping straps. The adjustment assembly comprises an elastomeric adjuster attached to one of the flexible clamping straps and an adjustment patch attached to the elastomeric adjuster. The adjustment patch is capable of matingly engaging one of the flexible clamping straps. The pairs of flexible support straps and flexible clamping straps engage with hook and loop type fasteners.
Applicant's U.S. Pat. No. 5,921,517 to Meuth discloses a clamp assembly for clamping an elongate member to a support member. The clamp assembly includes a flexible strap having first and second ends. The flexible strap extends substantially around the elongate and support members. The first and second ends are adapted to be coupled to each other or to the support member. The clamp assembly also includes a tensioner assembly having first and second tensioner bars spaced parallel to one another. Each of the first and second tensioner bars includes a bullnose face and the bullnose faces are in opposing relationship to one another. The tensioner assembly also includes an adjusting member for adjusting the spacing between the first and second tensioner bars. The flexible strap extends twice through the space between the first and second tensioner bars.
It is desirable to have a high strength clamp assembly that is lightweight and buoyant, easy to install, capable of being quickly installed, and able to withstand jarring contact with the inner well casing and protect the lines or pipes. It is also desirable that the high strength buoyant clamp assembly be economical and durable, in addition to firmly securing an elongate member to a support member. The clamp assembly should also provide protection against abrasion at the contact points with the clamped members.
The present invention is a high strength buoyant clamp assembly and method utilizing a flexible strap and a friction multiplier material to securely clamp an elongate member to a support member. The high strength clamp assembly is lightweight and buoyant, easy to install, capable of quick installation, and exceptionally durable by design to protect the lines or pipes from contact with each other and an inner well casing. The high strength clamp assembly is economical and firmly secures the clamped members to one another, and accommodates all variances of size for both the umbilical(s) and riser pipe(s) being clamped together.
The high strength buoyant clamp assembly includes a flexible strap having first and second ends. The flexible strap extends substantially around the elongate and support members. Affixed to the first end of the flexible strap is a pull tab which is adapted to be passed through an elongate loop affixed to the second end of the flexible strap. The flexible strap is secured by a tensioner assembly. Affixed to the exterior of the flexible strap are spaced buoyant wear blocks. Stitched to the interior of the flexible strap is a friction multiplier to improve the gripping of the elongate and support members. The tensioner assembly includes first and second tensioner bars spaced parallel to one another and attached to each other by buoyant capture bars. Each of the first and second tensioner bars includes a bullnose face and the bullnose faces are in opposing relationship to one another. The tensioner assembly also includes a pair of threaded adjusting members for adjusting the spacing between the first and second tensioner bars. In use, the first and second tensioner bars are situated substantially between the elongate member and the support member.
In order to more fully understand the drawings referred to in the detailed description of the present invention, a brief description of each drawing is presented, in which:
Referring now to the drawings in greater detail, the first embodiment of the high strength buoyant clamp assembly of the present invention, generally designated by the letter C, for clamping an umbilical or elongate member U to a support member S is shown in a first embodiment in
Referring to
The first and second ends 12 and 14, respectively, are adapted to be coupled to an elongate loop 8. The elongate loop 8 is preferably made from ultra-high molecular weight polyethylene (UHMW-PE) because of its superior wear resistance characteristics. UHMW-PE has the best wear resistance characteristics of any of the plastics. Referring to
Secured by high-strength polyester stitching T to the first end 12 of the flexible strap 10 is a pull-tab 12A to assist in the ease of handling and installation. The pull-tab 12A is preferably made of low density polyethylene (LDPE). As shown in
Referring to
Referring to
Still referring to
Preferably, a friction multiplier 74A is also stitched to the outer surface of the flexible strap 10 at the location where the first end 12 of the flexible strap 10 is passed back through the tensioner assembly 30 as will be explained below. It is to be understood that the friction multiplier 74A is made from the same material as the friction multiplier 74.
The tensioner assembly 30 includes a first tensioner bar 32 and a second tensioner bar 34 as shown in
The tensioner assembly 30 includes a pair of adjusting members 44 for altering the horizontal separation between the tensioner bars 32 and 34. Preferably, the first tensioner bar 32 has adjusting member lower and upper bores 32B and 32C, respectively. Adjusting member bores 32B and 32C have varying diameters. Referring to
Referring to
As shown in
The tensioner assembly 30 also includes a pair of capture bolts 50 for maintaining a connection between the first and second tensioner bars 32 and 34 in the event of failure or the adjusting members 44 or the unthreading of the adjusting members 44 from the second tensioner bar 34. The capture bolts 50 are preferably made from high density polyethylene (HDPE). Preferably, the second tensioner bar 34 has capture bolt lower and upper bores 34D and 34E, respectively. Capture bolt bores 34D and 34E have varying diameters. Referring to
Referring to
The installation of the first embodiment of the clamp assembly C will now be described in detail with reference to
The adjusting members 44 are rotated to threadedly drive the tensioner bars 32 and 34 toward each other, thus reducing the gap G. As is apparent from
The high strength clamp assembly C' comprises a strap 10, preferably flexible, having first and second ends 12 and 14, respectively, and a tensioner assembly 30 as described above. Referring to
Secured by high-strength polyester stitching T to the first end 12 of the flexible strap 10 is a pull-tab 12A, as described above, to assist in the ease of handling and installation. The pull-tab 12A is preferably made of low density polyethylene (LDPE).
Referring to
Still referring to
As shown in
The tensioner assembly 30 is the same as described above and includes a first tensioner bar 32 and a second tensioner bar 34 as shown in FIG. 4. It is to be understood that all of the other features of the tensioner assembly 30 are same as in the first embodiment.
The second embodiment of the clamp assembly C' includes a preformed receiving block 80 as shown in FIG. 4. The receiving block 80 is preferably made from polypropylene. An alternative receiving block 180 is shown in FIG. 5 and is preferably made from urethane, more preferably a two part urethane. It may be desirable to include glass balls (not shown) within the receiving block 180 for purposes of flotation. Although not shown, it is to be understood that the receiving block 80, 180 preferably has a length approximating the width of the flexible strap 10. The receiving block 80, 180 includes two or more receptacles 82 and 84 conformed to at least partially receive the corresponding elongate members U1 and U2. It is to be understood that the receptacles 82 and 84 may be different sizes depending upon the corresponding elongate members U1 and U2. Preferably, the receptacles 82 and 84 are arcuate-shaped along the length of the receiving block 80, 180.
The receiving block 80 includes a friction multiplier 76 attached to the receptacles 82 and 84. Preferably, the friction multiplier 76 is made of the same material as the friction multiplier 74. Preferably, the friction multiplier 76 is adhered to the receptacles 82 and 84 of the receiving block 80 with a thin layer of epoxy.
Referring to
Referring to
The preformed receiving block 180 provides the ability to firmly secure two or more umbilicals or elongated members U1 and U2 to the support member S. It is to be understood that the installation of the clamp assembly C' is similar to the installation of the clamp assembly C described above, however, the elongated members U1 and U2 are received in the receptacles 82 and 84 prior to the second end 14 of the flexible strap 10 being joined to the first end 12 by inserting the pull-tab 12A through the loop 8. All other steps of installation and use are similar in all respects to the installation and use of the clamp assembly C.
It is to be understood that the high strength buoyant clamp assembly of the present invention is very versatile and has applications in many fields. It is not intended to be limited to the drilling industry, but could be used in virtually any situation requiring the clamping of an elongate member to a support member.
It is to be understood that each of the clamp assemblies C and C' is a high strength buoyant clamp assembly utilizing a flexible strap and friction multiplier to securely clamp an elongate member to a support member. The high strength clamp assembly C, C' is lightweight and buoyant, easy to install, capable of quick installation, and exceptionally durable by design to protect the lines or pipes from contact with each other and the inner well casing. The high strength clamp assembly C, C' is economical and firmly secures the clamped members to one another. Further, it is to be understood that the clamp assembly C, C' may be made entirely from non-metallic components while providing a clamping force meeting or exceeding many metallic clamps, at a much reduced weight. The components from which the clamp assembly C, C' are made are either buoyant or else will not result in serious problems downhole if somehow they fail and fall to the bottom of the hole. As stated above, the clamp assembly C, C' is buoyant as an entire assembly, and is designed to hold all assembly parts captive.
The foregoing disclosure and description of the invention is illustrative and explanatory thereof, and various changes in the size, shape, and materials, as well as in the details of illustrative construction and assembly, may be made without departing from the spirit of the invention.
The foregoing disclosure and description of the preferred embodiment are illustrative and explanatory thereof, and various changes in the components, circuit elements, circuit configurations, and signal connections, as well as in the details of the illustrated circuitry and construction and method of operation may be made without departing from the spirit and scope of the invention.
Meuth, Thomas Larry, Brannan, Stanley
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